Expression and distribution of cell adhesion molecule uvomorulin in mouse preimplantation embryos

We have examined the synthesis and distribution of the cell adhesion molecule uvomorulin in mouse preimplantation embryos. Uvomorulin can already be detected on the cell surface of unfertilized and fertilized eggs but is not synthesized in these cells. Uvomorulin synthesis starts in late two-cell embryos and seems not to be correlated with the onset of compaction. The first signs of compaction are accompanied by a redistribution of uvomorulin on the surface of blastomeres. During compaction uvomorulin is progressively removed from the apical membrane domains of peripheral blastomeres. In compact morulae uvomorulin is no longer present on the outer surface of the embryo but is localized predominantly in membrane domains involved in cell-cell contacts of adjacent outer blastomeres. On inner blastomeres of compact morulae uvomorulin remains evenly distributed. This uvomorulin distribution once established during compaction is maintained and also found in the blastocyst: on trophectodermal cells uvomorulin localization is very similar to that in adult intestinal epithelial cells while uvomorulin remains evenly distributed on the surface of inner cell mass cells. The possible role of the redistribution of uvomorulin for the generation of trophectoderm and inner cell mass in early mouse embryos is discussed.     

Cell specific loss of polarity-inducing ability by later stage mouse preimplantation embryos

The individual blastomeres of the preimplantation mouse embryo become polarized during the 8-cell stage. Microvilli become restricted to the free surface of the embryo and this region of the membrane shows increased labeling with FITC-Con A and trinitrobenzenesulfonate (TNBS). Previous studies have shown that this polarity develops in response to asymmetric cell-cell contact with stage specific induction competent blastomeres. In the present study, the ability of later stage embryos to induce 8-cell polarization has been investigated. Newly-formed, nonpolar 8-cell stage blastomeres (1/8 cells) were isolated, then aggregated with morulae, inner cell clusters (from morulae), blastocysts, or inner cell masses (ICM) and cultured for 8 hr. Aggregates were then assayed for polarity. The results show a hierarchy of inducing ability, with the ICM and IC cluster possessing greater activity than the morula and polar trophectoderm of the early blastocyst, while the mural trophectoderm shows very little inducing activity. Furthermore, the inducing ability of the polar trophectoderm decreases with complete expansion and hatching of the blastocyst. These results indicate that the ability to induce 8-cell blastomere polarization is retained by the embryo beyond the 8-cell stage and that this ability is lost with further differentiation.     

Changes in the organization of the actin cytoskeleton during preimplantation development of the pig embryo

The organization of the actin cytoskeleton was studied in unfertilized porcine oocytes and preimplantation stage embryos from Day 1 through Day 8 of development. Fixed and detergent-extracted oocytes and embryos were analyzed by fluorescence microscopy after staining with either rhodamine-phalloidin to localize filamentous actin or with affinity-purified anti-actin antibodies to localize the total immunodetectable actin. Whereas unfertilized oocytes contain immunoreactive cytoplasmic actin, rhodamine-phalloidin binding is not detected until fertilization when a prominent cortical staining pattern becomes apparent. In early cleavage stage embryos, filamentous actin is concentrated in the cell cortex of blastomeres especially at sites of cell-cell contact. Compacting morulae exhibit a marked accumulation of actin at the margins of blastomeres where numerous interdigitating cell processes are located. The predominantly pericellular distribution of actin becomes a distinguishing feature of trophectodermal cells in the expanding blastocyst at Day 6 of development; these cells form a prominent actin-limited zone circumscribing the inner cell mass. In Day 8 blastocysts, three cell types are present that are readily distinguishable based upon their actin displays among other cytological features. Trophectodermal cells exhibit continuous actin-rich lateral borders and stress fibers along their basal surface. Inner cell mass cells contain a discontinuous actin boundary and prominent foci of actin along their blastocoelic surface. Lining the blastocoel are patches of endodermal cells in which the actin is exclusively cortical. The data are discussed with respect to differences between species and the chronology of actin rearrangements during preimplantation development of the porcine embryo.     

FAM deubiquitylating enzyme is essential for preimplantation mouse embryo development.

FAM is a developmentally regulated substrate-specific deubiquitylating enzyme. It binds the cell adhesion and signalling molecules beta-catenin and AF-6 in vitro, and stabilises both in mammalian cell culture. To determine if FAM is required at the earliest stages of mouse development we examined its expression and function in preimplantation mouse embryos. FAM is expressed at all stages of preimplantation development from ovulation to implantation. Exposure of two-cell embryos to FAM-specific antisense, but not sense, oligodeoxynucleotides resulted in depletion of the FAM protein and failure of the embryos to develop to blastocysts. Loss of FAM had two physiological effects, namely, a decrease in cleavage rate and an inhibition of cell adhesive events. Depletion of FAM protein was mirrored by a loss of beta-catenin such that very little of either protein remained following 72h culture. The residual beta-catenin was localised to sites of cell-cell contact suggesting that the cytoplasmic pool of beta-catenin is stabilised by FAM. Although AF-6 levels initially decreased they returned to normal. However, the nascent protein was mislocalised at the apical surface of blastomeres. Therefore FAM is required for preimplantation mouse embryo development and regulates beta-catenin and AF-6 in vivo.     

Effects of brefeldin-A and monensin on organelle distribution and morphology in the preimplantation mouse embryo

 The intracellular trafficking of integral membrane and secreted proteins is likely to be a key element involved in the morphogenesis and differentiation of the early mammalian embryo. In this study, we used transmission electron microscopy (TEM) to analyse the effects of brefeldin-A (BFA) and monensin, well known inhibitors of vesicular protein trafficking in somatic cells, on the structure of preimplantation mouse embryos. Both BFA and monensin distinctively altered the morphology of Golgi compartments in the blastomeres of treated morulae. BFA-treated morulae lacked recognizable Golgi complexes but possessed heterogeneous organelle clusters consisting of an abundance of smooth tubular and vesicular membrane compartments in addition to mitochondria, endosomes and lysosomes. Treatment of morulae with monensin was associated with swelling of Golgi compartments in addition to altering the morphology of mitochondria, lysosomes and the plasma membrane. BFA, and to a lesser extent monensin, inhibited cytokinesis as evidenced by the detection of binucleate blastomeres. In addition, BFA induced morulae to decompact. These latter effects have not been reported previously for these agents in mammalian somatic cell lines or other vertebrate or invertebrate embryos. These results provide the first demonstration of the structural effects of BFA and monensin on cells of the early mammalian embryo, some of which are consistent with the known actions of these agents on components of the vesicular protein trafficking system in mammalian somatic cells. This information serves as a foundation for the further use of these agents in studies of vesicular protein trafficking as an agent of preimplantation morphogenesis. Received: 22 April 1996 / Accepted: 4 December 1996     

An assay using embryo aggregation chimeras for the detection of nonlethal changes in X-irradiated mouse preimplantation embryos

We have developed a short-term in vitro assay for the detection of sublethal effects produced by very low levels of ionizing radiation. The assay utilizes mouse embryo aggregation chimeras consisting of one irradiated embryo paired with an unirradiated embryo whose blastomeres have been labeled with fluorescein isothiocyanate (FITC). X irradiation (from 0.05 to 2 Gy) and chimera construction were performed with four-cell stage embryos, and the chimeras were cultured for 40 h to the morula stage. The morulae were partially dissociated with calcium-free culture medium and viewed under phase contrast and epifluorescence microscopy to obtain total embryo cell number and the cellular contribution of irradiated (unlabeled) and control (FITC labeled) embryos per chimera. In chimeras where neither embryo was irradiated, the ratio of the unlabeled blastomeres to the total number of blastomeres per chimera embryo was 0.50 (17.8 +/- 5.6 cells per unlabeled embryo and 17.4 +/- 5.5 cells per FITC-labeled partner embryo). However, in chimeras formed after the unlabeled embryos were irradiated with as little as 0.05 Gy, the ratio of unlabeled blastomeres to the total number of blastomeres per chimera embryo was 0.43 (P less than 0.01). The apparent decreases in cell proliferation were not observed in irradiated embryos that were merely cocultured with control embryos, regardless of whether the embryos were zona enclosed or zona free. We conclude that very low levels of radiation induce sublethal changes in cleaving embryos that are expressed as a proliferative disadvantage within two cell cycles when irradiated embryos are in direct cell-to-cell contact with unirradiated embryos.     

Cytoskeleton organization during oogenesis, fertilization and preimplantation development of the mouse

The organization and role of the cytoskeletal networks (mainly microtubules and microfilaments) during oogenesis, fertilization and preimplantation development of the mouse are described given the importance of cell-cell interactions and of the subcellular organization in events leading to the formation of the first two lineages of the mouse embryo.     

Spectrin synthesis in the preimplantation mouse embryo

The preimplantation mouse embryo expresses two polypeptides, Mr 240,000 and Mr 235,000, that are immunologically cross-reactive with antibody to the alpha and beta subunits of mouse brain spectrin. We investigated the synthesis of the spectrin subunits in the Triton-soluble and Triton-insoluble fractions of fertilized eggs, two-cell embryos, compacted morulae, and blastocysts labeled with L-[35S]methionine. Synthesis of embryonic spectrin began in the Triton-soluble fraction with significant levels of alpha-spectrin synthesis first detected in the morula stage and significant levels of beta-spectrin synthesis detected in the blastocyst stage. Incorporation of newly synthesized alpha- and beta-spectrin into the cytoskeletal fraction took place in the blastocyst when equal amounts of both subunits were assembled. Previous studies have shown Triton-insoluble spectrin to be concentrated in regions of cell-cell contact in the embryo (J. S. Sobel and M. A. Alliegro, 1985, J. Cell Biol. 100, 333-336). The temporal and spatial correlation between the assembly of newly synthesized spectrin and its concentration in regions of cell apposition is consistent with the hypothesis that cell contact may influence the assembly of embryonic spectrin.     

Phosphorylation of ezrin on threonine T567 plays a crucial role during compaction in the mouse early embryo

The preimplantation development of the mouse embryo leads to the divergence of the first two cell lineages, the inner cell mass and the trophectoderm. The formation of a microvillus pole during compaction at the eight-cell stage and its asymmetric inheritance during mitosis are key events in the emergence of these two cell populations. Ezrin, a member of the ERM protein family, seems to be involved in the formation and stabilization of this apical microvillus pole. To further characterize its function in early development, we mutated the key residue T567, which was reported to be essential for regulation of ezrin function through phosphorylation. Here, we show that expression of ezrin mutants in which the COOH-terminal threonine T567 was replaced by an aspartate (to mimic a phosphorylated residue; T567D) or by an alanine (to avoid phosphorylation; T567A) interferes with E-cadherin function and disrupts the first morphogenetic events of development: compaction and cavitation. The active mutant ezrin-T567D induces the formation of numerous and abnormally long microvilli at the surface of blastomeres. Moreover, it localizes all around the cell cortex and inhibits cell-cell adhesion and cell polarization at the eight-cell stage. During the following stages, only half of the embryos are able to compact and finally to cavitate. In those embryos, the amount of ezrin-T567D decreases in the basolateral areas, while the proportion of adherens junctions increases. The reverse inactive mutant ezrin-T567A is mainly cytoplasmic and does not perturb compaction at the eight-cell stage. However, at the 16-cell stage, it relocalizes at the basolateral cortex, leading to a strong decrease in the surface of adherens junctions, and finally, embryos abort development. Our results show that ezrin is directly involved in the formation of microvilli in the early mouse embryo. Moreover, they indicate that maintenance of ezrin in basolateral areas prevents microvilli breakdown and inhibits the formation of normal cell-cell contacts mediated by E-cadherin, thereby impairing blastomeres polarization and morphogenesis of the blastocyst.     

Accumulation of acetylcholinesterase at newly formed nerve--muscle synapases.

The mechanism of fluid transport in the developing preimplantation mouse embryo has been studiedin vitro by inhibiting zonular tight junction formation. Compaction, the morphogenetic process permitting zonular blastomere adhesions at the 8-cell stage, was suppressed by lowering extracellular calcium (Ca). The Ca threshold required for compaction is 0.04–0.06 mM, and in concentrations above the threshold, the rate of compaction is concentration dependent, whereas the rate of blastocyst formation is not and proceeds normally. At 0.02 mM Ca, both compaction and blastocyst development are completely prevented. Although focal tight and gap junctions are present, zonular tight junctions do not develop. We conclude that Ca is required for the maximization of cell-cell contact, but not for focal tight junction and gap junction formation. When early morulae are cultured in 0.02 mM Ca, small trophoblastic vesicles develop frequently with intracellular fluid vacuoles. If early 8-cell embryos are similarly cultured, cell division continues and many blastomeres acquire small intracellular membrane-bounded vaculoes. These coalesce, the cell volume increases, and the nucleus becomes eccentrically positioned, resulting in a giant vacuolated blastomere reminiscent of a miniaturized blastocyst. We propose that (1) vacuole formation may be an exaggeration of an intermediate intracellular step in fluid transport and (2) normal cell polarity established by zonular tight junctions is required for transcellular fluid transport.     

Antibodies to a renal Na+/glucose cotransport system localize to the apical plasma membrane domain of polar mouse embryo blastomeres.

Mouse preimplantation embryos were examined for the cell surface expression of epitopes that cross-react with antibodies to a 75-kDa subunit of a purified porcine renal brush border Na+/glucose cotransport system. A Na+ cotransport system is hypothesized to reside in the apical plasma membrane domain of mouse polar blastomeres and to be associated with the induction of their apical-basal polarity. Western blot analysis showed that unfertilized oocytes as well as preimplantation embryos contain a cross-reacting antigen with an apparent molecular weight of about 75,000. Embryos and their isolated blastomeres were double-labeled and assayed by indirect immunofluorescence (IIF) for the expression of epitopes (visualized by labeling with rabbit antiserum or mouse monoclonal IgG to cotransporter followed by the appropriate rhodamine-conjugated second antibodies) and for the development of cell surface polarity (visualized by the apical restriction of fluoresceinated succinylated concanavalin A binding; FS Con A). IIF did not detect these epitopes until after the second cleavage when 4-cell embryos expressed low-to-moderate levels. Although epitopes were expressed on all surfaces of 4-cell blastomeres, some blastomeres expressed more epitopes on their apical surfaces than on their basolateral ones. All precompaction 8-cell embryos expressed epitopes, with expression being greater apically on some blastomeres. The level of expression appeared to reach a maximum on morulae and to decline on cavitating embryos. Assays performed on isolated blastomeres from postcompaction embryos showed that by the 16-cell stage epitope expression appeared to become restricted to FS Con A-labeled apical plasma membrane domains and was no longer evident on basolateral domains. This apparent apical restriction of epitope expression was confirmed by electron microscopic examination of immunogold-labeled isolated polar 16-cell blastomeres. These results demonstrate that preimplantation mouse embryos contain an antigen(s) that is immunologically and structurally similar to a 75-kDa renal Na+/glucose cotransporter. The onset of cell surface expression of this antigen precedes development of the stable polar phenotype.     

Myosin rings and spreading in mouse blastomeres

The relationship between myosin organization and cell spreading in the preimplantation mouse embryo was studied by indirect immunofluorescence in embryos cultured on lectin-coated substrates. Binding of cell surface polysaccharides to substrate-bound concanavalin A and wheat germ agglutinin induced changes in myosin distribution that resembled those which occur during cell-cell contact interaction. This involved an initial loss of myosin from the contact region that was associated with the development of stable cell-substrate attachments. In addition, a ring of myosin was formed along the edge of the cells' contact to the substrate. The presence of such a ring may be related to the potential for subsequent cell spreading. A myosin ring was also identified in the apical junctional region of the outer morula cells where it similarly separated the cell periphery into contacted and free peripheral domains. Following these changes in myosin organization the embryos spread on the substrate by extension of lamellipodia. These movements were coupled to the dissolution of the myosin ring and the reorganization of myosin into filament bundles. The sequence of changes in the pattern of myosin distribution suggests that contact regulation of myosin organization plays an important role in controlling the spreading behavior of blastomeres and perhaps more generally in the organization of cells into epithelia.     

Laser Fusion of Mouse Embryonic Cells and Intra-Embryonic Fusion of Blastomeres without Affecting the Embryo Integrity

Manipulation with early mammalian embryos is the one of the most important approach to study preimplantation development. Artificial cell fusion is a research tool for various biotechnological experiments. However, the existing methods have various disadvantages, first of them impossibility to fuse selected cells within multicellular structures like mammalian preimplantation embryos. In our experiments we have successfully used high repetition rate picosecond near infrared laser beam for fusion of pairs of oocytes and oocytes with blastomeres. Fused cells looked morphologically normal and keep their ability for further divisions in vitro. We also fused two or three blastomeres inside four-cell mouse embryos. The presence of one, two or three nuclei in different blastomeres of the same early preimplantation mouse embryo was confirmed under UV-light after staining of DNA with the vital dye Hoechst-33342. The most of established embryos demonstrated high viability and developed in vitro to the blastocyst stage. We demonstrated for the first time the use of laser beam for the fusion of various embryonic cells of different size and of two or three blastomeres inside of four-cell mouse embryos without affecting the embryo’s integrity and viability. These embryos with blastomeres of various ploidy maybe unique model for numerous purposes. Thus, we propose laser optical manipulation as a new tool for investigation of fundamental mechanisms of mammalian development.     

Four-cell stage mouse blastomeres have different developmental properties

Blastomeres of the early mouse embryo are thought to be equivalent in their developmental properties at least until the eight-cell stage. However, the experiments that have led to this conclusion could not have taken into account either the spatial origin of individual blastomeres or the spatial allocation and fate of their progeny. We have therefore readdressed this issue having defined cell lineages in mouse embryos undergoing different patterns of cleavage in their second division cycle. This has enabled us to identify a major group of embryos in which we can predict not only the spatial origin of each given four-cell blastomeres, but also which region of the blastocyst is most likely to be occupied by its progeny. We show that a pattern of second cleavage divisions in which a meridional division is followed by one that is equatorial or oblique allows us to identify blastomeres that differ in their fate and in their developmental properties both from each other and from their cousins. We find that one of these four-cell stage blastomeres that inherits some vegetal membrane marked in the previous cleavage cycle tends to contribute to mural trophectoderm. The progeny of its sister tend to donate cells to part of the ICM lining the blastocyst cavity and its associated trophectoderm. Chimaeras made entirely of these equatorially or obliquely derived blastomeres show developmental abnormalities in both late preimplantation and early postimplantation development. By contrast, chimaeras made from four-cell stage blastomeres from early meridional divisions develop normally. The developmental defects of chimaeras made from the most vegetal blastomeres that result from later second cleavages are the most severe and following transplantation into foster mothers they fail to develop to term. However, when such individual four-cell blastomeres are surrounded by blastomeres from random positions, they are able to contribute to all embryonic lineages. In conclusion, this study shows that while all four-cell blastomeres can have full developmental potential, they differ in their individual developmental properties according to their origin in the embryo from as early as the four-cell stage.